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Canine Intestinal Organoids in a Dual-Chamber Permeable Support System

作者: Vojtech Gabriel1, Christopher Zdyrski1, Dipak K. Sahoo2, Kimberly Dao3, Agnes Bourgois-Mochel2, Todd Atherly3, Marilyn N. Martinez4, Donna A. Volpe5, Jamie Kopper2, Karin Allenspach2,3, Jonathan P. Mochel1,3 1Department of Biomedical Sciences, College of Veterinary Medicine,Iowa State University, 2Department of Veterinary Clinical Sciences, College of Veterinary Medicine,Iowa State University, 33D Health Solutions Inc., 4Office of New Animal Drug Evaluation,Center for Veterinary Medicine, Food and Drug Administration, 5Division of Applied Regulatory Science, Office of Clinical Pharmacology, Office of Translational Sciences,Center for Drug Evaluation and Research, Food and Drug Administration
简介:

Overview

This article presents a protocol for culturing canine intestinal organoids using a dual-chamber, permeable support system. The approach enhances the reliability of drug permeability predictions in both canine and human models.

Key Study Components

Area of Science

  • Biomedical research
  • Organoid technology
  • Drug permeability studies

Background

  • Traditional 2D cell lines have limitations in biomedical research.
  • Canine organoid technology offers a more reliable model.
  • The dual-chamber system facilitates better experimental conditions.
  • Standardized procedures are essential for consistent results.

Purpose of Study

  • To improve the prediction of oral drug permeability.
  • To provide a reliable model for studying drug interactions.
  • To explore applications in microbiology and viral uptake studies.

Methods Used

  • Seeding organoids in a dual-chamber system.
  • Maintaining monolayers for drug permeability assays.
  • Documenting experimental procedures in detail.
  • Monitoring cell health and integrity throughout experiments.

Main Results

  • The dual-chamber system enhances drug permeability assessments.
  • Canine organoids provide a more accurate model compared to 2D lines.
  • Standardization improves reproducibility of results.

Conclusions

  • The study demonstrates the effectiveness of canine organoids in drug research.
  • Future applications could extend to various biomedical fields.
  • Continued refinement of methods will enhance experimental outcomes.

Frequently Asked Questions

What are canine intestinal organoids?
Canine intestinal organoids are 3D structures derived from canine intestinal cells that mimic the function and architecture of the intestine.
How does the dual-chamber system work?
The dual-chamber system allows for the separation of the apical and basolateral sides of the organoids, facilitating drug permeability studies.
What are the advantages of using organoids over 2D cell lines?
Organoids provide a more physiologically relevant environment, improving the accuracy of drug permeability predictions.
Can this method be applied to other types of research?
Yes, the dual-chamber system can be utilized in microbiology, viral uptake studies, and drug-drug interaction research.
What is the significance of standardization in this research?
Standardization ensures reproducibility and reliability of experimental results, which is crucial for scientific validation.

Here, we present a protocol describing the culture of canine intestinal organoids in a dual-chamber, permeable support system. Organoid seeding in the permeable supports, the monolayer maintenance, and subsequent drug permeability experiments are described.

标签: Canine Intestinal Organoids,    Dual-chamber Permeable Support System,    Experimental 2D Cell Lines,    Oral Permeability,    Therapeutic Drug Candidates,    Microbiology Research,    Drug-drug Interactions,    Drug Transport Mechanisms,    Caco-2 Model,    MDCK Model,    Gastrointestinal Anatomy,    Intestinal Microflora,    In Vitro Tool,    Canine Organoid Isolation,    Monolayer Maintenance Protocol,   
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